2019
DOI: 10.1103/physrevd.99.095011
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FASER’s physics reach for long-lived particles

Abstract: FASER, the ForwArd Search ExpeRiment, is an approved experiment dedicated to searching for light, extremely weakly-interacting particles at the LHC. Such particles may be produced in the LHC's high-energy collisions and travel long distances through concrete and rock without interacting. They may then decay to visible particles in FASER, which is placed 480 m downstream of the ATLAS interaction point. In this work we briefly describe the FASER detector layout and the status of potential backgrounds. We then pr… Show more

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Cited by 332 publications
(361 citation statements)
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References 113 publications
(297 reference statements)
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“…Overall, we find that the DUNE MPD will be able to extend sensitivity to a dark photon in the sub-GeV mass regime for kinetic mixing in the ε 2 ≈ 10 −16 − 10 −14 range. This complements other future experiments, such as FASER [73,74], SHiP [66], and SeaQuest [67], which will be sensitive to larger values of ε 2 , as the detectors associated with these proposals are significantly closer to their production targets. If dark photons exist and are produced in this type of environment, then those produced at CERN (for detection at FASER/SHiP) would be much more boosted than those produced at DUNE.…”
Section: Dark Photon Sensitivitysupporting
confidence: 54%
“…Overall, we find that the DUNE MPD will be able to extend sensitivity to a dark photon in the sub-GeV mass regime for kinetic mixing in the ε 2 ≈ 10 −16 − 10 −14 range. This complements other future experiments, such as FASER [73,74], SHiP [66], and SeaQuest [67], which will be sensitive to larger values of ε 2 , as the detectors associated with these proposals are significantly closer to their production targets. If dark photons exist and are produced in this type of environment, then those produced at CERN (for detection at FASER/SHiP) would be much more boosted than those produced at DUNE.…”
Section: Dark Photon Sensitivitysupporting
confidence: 54%
“…As discussed in section 4.2, the particle physics constraints hence need to be adapted correspondingly, and we thus only keep those limits shown in figure 3 that are still relevant in this situation (and add that from BaBar [103] for the case of m S = 1 GeV). 13 For invisible decays, furthermore, there is also no upper boundary to the area excluded by energy loss arguments in supernovae (as in figure 3). This implies that for 2m χ < m S 0.2 GeV, unlike the situation in figure 5 for visible decays, the combination of SN bounds and SIDM constraints indeed does combine to a very competitive bound on σ SI (though, as discussed in section 5.4, SN limits should be interpreted with care).…”
Section: Resultsmentioning
confidence: 99%
“…At the intensity frontier, in particular, there is a plethora of both ongoing and planned activities that aim to explore new physics in the sub-GeV range. Prominent examples for the latter include, but are not limited to, planned upgrades to current experiments such as NA62 [9] and NA64 [10], the recently approved LHC add-on FASER [11][12][13][14][15] as well as dedicated new experiments like LDMX [16] and SHiP [17][18][19] that are planned to be run at the new Beam Dump Facility at CERN. Finally there are proposals for LHC based intensity frontier experiments such CODEX-b [20] and MATHUSLA [21][22][23][24].…”
Section: Introductionmentioning
confidence: 99%
“…LHCb [65,66], Belle-II [60,67], AWAKE [68] (10 16 electrons of 50 GeV), HPS [69], SeaQuest [70], LDMX [71] (HL-LDMX with E beam = 16 GeV), FASER [72] (LHC Run 3 with 150 fb −1 ), NA62 [73], and SHiP [74]. Additionally, the NA64 bounds should improve soon [75].…”
Section: A Dark Neutron Dark Mattermentioning
confidence: 99%
“…The constraints specific to our models, namely that m γ ≤ m π 0 /2 and that the dark photon decays before SM neutrinos decouple around T ∼ 3 MeV, are in light blue and red, respectively. Also shown in rainbow colors are projections from future experiments [60,[65][66][67][68][69][70][71][72][73][74]. Left: Viable parameter space for the dark neutron dark matter case with the predicted m n = 1.33 GeV and assuming m π ∼ 0.5m n .…”
Section: B Dark Proton and Pion Dark Mattermentioning
confidence: 99%